Optimum activity of the phosphofructokinase from Ascaris suum requires more than one metal ion

Phosphofructokinase (PFK) catalyzes the phosphorylation of fructose 6-phosphate (F6P) to give fructose 1,6-bisphosphate (FBP) using MgATP as the phosphoryl donor. As the concentration of Mg(2+) increases above the concentration needed to generate the MgATP chelate complex, a 15-fold increase in the initial rate was observed at low MgATP. The effect of Mg(2+) is limited to V/K(MgATP), and initial rate studies indicate an equilibrium-ordered addition of Mg(2+) before MgATP. Isotope partitioning of the dPFK:MgATP complex indicates a random addition of MgATP and F6P at low Mg(2+), with the rate of release of MgATP from the central E:MgATP:F6P complex 4-fold faster than the net rate constant for catalysis. This can be contrasted with the ordered addition of MgATP prior to F6P at high Mg(2+). The addition of fructose 2,6-bisphosphate (F26P(2)) has no effect on the mechanism at low Mg(2+), with the exception of a 4-fold increase in the affinity of the enzyme for F6P. At high Mg(2+), F26P(2) causes the kinetic mechanism to become random with respect to MgATP and F6P and with MgATP released from the central complex half as fast as the net rate constant for catalysis. The latter is in agreement with previous studies [Gibson, G. E., Harris, B. G., and Cook, P. F. (1996) Biochemistry 35, 5451-5457]. The overall effect of Mg(2+) is a decrease in the rate of release of MgATP from the E:MgATP:F6P complex, independent of the concentration of F26P(2).     

Effects of magnesium, manganese and adenosine triphosphate ions on pyruvate carboxylase from baker''s yeast

1. Pyruvate carboxylase from baker's yeast acts with either MgATP(2-) or MnATP(2-) as substrate. The optimum pH for the enzyme reaction is 8.0 with MgATP(2-) and 7.0 with MnATP(2-). 2. When the reaction velocity is plotted against MgATP(2-) (or MnATP(2-)) concentration slightly sigmoid curves are obtained, either in the presence or in the absence of acetyl-CoA (an allosteric activator). In the presence of excess of free Mg(2+) (or Mn(2+)) the curves turn into hyperbolae, whereas in the presence of excess of free ATP(4-) the apparent sigmoidicity of the curves increases. 3. The sigmoidicity of the plots of v against MgATP(2-) (or MnATP(2-)) concentration can be explained by the inhibitory effect of free ATP(4-), the concentration of which, in the experimental conditions employed, is significant and varies according to the total concentration of the ATP-magnesium chloride (or ATP-manganese chloride) mixture. Free ATP(4-) behaves as a negative modifier of yeast pyruvate carboxylase. 4. The effect of high concentrations of Mg(2+) (or Mn(2+)) on the kinetics of yeast pyruvate carboxylase can be explained as a deinhibition with respect to ATP(4-), instead of a direct enzyme activation. 5. At pH6.5 manganese chloride is more effective than magnesium chloride as enzyme activator even in the presence of a great excess (16-fold) of the latter. This is consistent with a significant contribution of the MnATP(2-) complex to the activity of yeast pyruvate carboxylase, in medium conditions resembling those existing inside the yeast cell (pH6.25-6.75; 12mm-magnesium chloride and 0.75mm-manganese chloride). 6. The physiological significance of the enzyme inhibition by free ATP(4-) is doubtful since the Mg(2+) and Mn(2+) concentrations reported to exist inside the yeast cell are sufficient to decrease ATP(4-) concentrations to ineffective values.     

Purification and Mn2+ activation of Rhodospirillum rubrum nitrogenase activating enzyme.

The Fe protein activating enzyme for Rhodospirillum rubrum nitrogenase was purified to approximately 90% homogeneity, using DE52-cellulose chromatography and sucrose density gradient centrifugation. Activating enzyme consists of a single polypeptide of molecular weight approximately 24,000. ATP was required for catalytic activity, but was relatively ineffective in the absence of Mg2+. When the concentration of MgATP2- was held in excess, there was an additional requirement for a free divalent metal ion (Mn2+) for enzyme activity. Kinetic experiments showed that the presence of Mg2+ influenced the apparent binding of Mn2+ by the enzyme, resulting in a lowering of the concentration of Mn2+ required to give half-maximum activity (K alpha) as the free Mg2+ concentration was increased. A low concentration of Mn2+ had a sparing effect on the requirement for free Mg2+. There is apparently a single metal-binding site on activating enzyme which preferentially binds Mn2+ as a positive effector, and free Mg2+ can compete for this site.     

The steady-state kinetic mechanism of ATP hydrolysis catalyzed by membrane-bound (Na+ + K+)-ATPase from ox brain. I. Substrate identity

A detailed steady-state kinetic investigation of the hydrolysis of ATP catalyzed by (Na+ + K+)-ATPase is reported. The activity was studied in the presence of (i) Na+ (130 mM), K+ (20 mM) and micromolar ATP concentrations and Na+ (150 mM) the ('Na+-enzyme'). The data obtained lead to the following results: 1. The action of each enzyme may be described by a simple kinetic mechanism with one (Na+-enzyme) or two ((Na+ + K+)-enzyme) dead-end Mg complexes. 2. For both enzymes, both MgATP and free ATP are substrates, with Mg2+, in the latter case, as the second substrate. 3. For each enzyme, the complete set of kinetic constants (seven for the Na+-enzyme, eight for the (Na+ + K+)-enzyme) are determined from the data. 4. For each enzyme it is shown that, in the alternate substrate mechanism obtained, the ratio of net steady-state flux along the 'MgATP pathway' to that of the 'ATP-Mg pathway' increases linearly with the concentration of free Mg2+. The parameters of this function are determined from the data. As a result of this, at high (greater than 3 mM) free Mg2+ concentrations the alternate substrate mechanism degenerates into a 'limiting' kinetic mechanism, with MgATP as the (essentially) sole substrate, and Mg2+ as an uncompetitive (Na+-enzyme) or non-competitive ((Na+ + K+)-enzyme) inhibitor.     

Studies on ouabain-complexed (Na+ +K+)-ATPase carried out with vanadate

Vanadate is able to promote the binding of ouabain to (Na+ +K+)-ATPase and it is shown that vanadate is trapped in the enzyme-ouabain complex. Also ouabain-bound enzyme, the formation of which was facilitated by (Mg2+ +Na+ +ATP) or (Mg2+ +Pi), is accessible to vanadate when washed free of competing ligands used for the promotion of ouabain binding. For vanadate binding to (Na+ +K+)-ATPase and to enzyme-ouabain complexes a divalent cation (Mg2+ or Mn2+) is indispensable, indicating that the cation does not remain attached to the ouabain-bound enzyme. K+ further increases vanadate binding in the absence of ouabain, but seems to have no additional role in case of vanadate binding to enzyme-ouabain complexes. Mn2+ is more efficient than Mg2+ in promoting binding of vanadate and ouabain to (Na+ +K+)-ATPase. That K+ in combination with Mn2+, in analogy with the effect in combination with Mg2+, increases the equilibrium binding level of vanadate and decreases that of ouabain does not seem to favour the hypothesis of selection of a special E2-subconformation by Mn2+. The vanadate-trapped enzyme-ouabain complex was examined for simultaneous nucleotide binding which could demonstrate a two-substrate mechanism per functional unit of the enzyme. The acceleration by (Na+ +ATP) of ouabain release from the (Mg2+ +Pi)-facilitated enzyme-ouabain complex does not, as anticipated, support such a mechanism. On the other hand, the deceleration of vanadate release as well as of ouabain release from a (Mg2+ +vanadate)-promoted complex could be consistent with a two-substrate mechanism working out-of-phase.     

Mechanistic studies of Escherichia coli adenosine-5'-phosphosulfate kinase

Adenosine-5'-phosphosulfate kinase (APS kinase) catalyzes the formation of 3'-phosphoadenosine 5'-phosphosulfate (PAPS), the major form of activated sulfate in biological systems. The enzyme from Escherichia coli has complex kinetic behavior, including substrate inhibition by APS and formation of a phosphorylated enzyme (E-P) as a reaction intermediate. The presence of a phosphorylated enzyme potentially enables the steady-state kinetic mechanism to change from sequential to ping-pong as the APS concentration decreases. Kinetic and equilibrium binding measurements have been used to evaluate the proposed mechanism. Equilibrium binding studies show that APS, PAPS, ADP, and the ATP analog AMPPNP each bind at a single site per subunit; thus, substrates can bind in either order. When ATPgammaS replaces ATP as substrate the V(max) is reduced 535-fold, the kinetic mechanism is sequential at each APS concentration, and substrate inhibition is not observed. The results indicate that substrate inhibition arises from a kinetic phenomenon in which product formation from ATP binding to the E. APS complex is much slower than paths in which product formation results from APS binding either to the E. ATP complex or to E-P. APS kinase requires divalent cations such as Mg(2+) or Mn(2+) for activity. APS kinase binds one Mn(2+) ion per subunit in the absence of substrates, consistent with the requirement for a divalent cation in the phosphorylation of APS by E-P. The affinity for Mn(2+) increases 23-fold when the enzyme is phosphorylated. Two Mn(2+) ions bind per subunit when both APS and the ATP analog AMPPNP are present, indicating a potential dual metal ion catalytic mechanism.     

Comparison of bone and osteosarcoma adenylate cyclase. Effects of Mg2+, Ca2+, ATP4? and HATP3? in the assay mixture

The effects of Mg(2+) and Ca(2+) on bone and osteosarcoma adenylate cyclase were investigated. The concentrations of the cations and other ionic species in the assay mixture were calculated by solving the simultaneous equations describing the relevant ionic interactions (multiple equilibria). We re-examined the effects of HATP(3-) and ATP(4-) on enzyme activity and found that (i) the concentration of the minor ATP species is less than 1% of that of MgATP(2-), and their ratio to MgATP(2-) is constant if Mg(2+) and H(+) concentrations are unchanged; (ii) Mg(2+) addition decreased the ratio of the minor species to MgATP(2-) and increased the enzyme activity, but no meaningful kinetic model could attribute this effect of HATP(3-) or ATP(4-). On the other hand, kinetic analysis of Mg(2+) effects showed: (i) stimulation via two metal sites, separate from the catalytic (MgATP(2-)) site, with apparent K(m) values of approximately 1 and 8mm; (ii) that the low affinity increased towards the higher one when the enzyme activity rose as a result of increased substrate or guanine nucleotide concentrations, this effect being less pronounced in tumour; (iii) conversely, that two apparent affinities for MgATP(2-) merged into one at high Mg(2+) concentration; (iv) kinetically, that this relationship is of the mixed con-competitive type, which is consistent with a role for Mg(2+) as a requisite activator, and binding occurring in non-ordered sequence. Analysis of the Ca(2+) effects showed: (i) competition with Mg(2+) at the metal site (K(i) 20mum for bone and 40mum for tumour); (ii) that relative to the substrate the inhibition was uncompetitive, i.e. velocity decreased and affinity increased proportionally, which is consistent with Ca(2+) binding after substrate binding. These findings support the existence of interacting enzyme complexes, losing co-operativity at increased enzyme activity. They also indicate a potential physiological role for Ca(2+) in enzyme regulation and point to quantitative differences between bone and tumour with regard to these properties.     

Role of calcium as an inhibitor of rat liver carbamylphosphate synthetase I

The mechanism of Ca2+ inhibition of carbamylphosphate synthetase I has been investigated using purified enzyme obtained from livers of rats fed a high protein diet. Binding of Mn2+ to the enzyme was measured by EPR techniques at pH 7.8, and Scatchard plots of the data indicated one Mn2+-binding site with a K'd of 13 microM. From competition studies between Mn2+ and Ca2+ or Mg2+ binding, values of 180 microM were obtained for K'd (Mg) and 193 microM for K'd (Ca). A nonlinear least squares curve fitting program was used to calculate the K'm for MgATP2- at the metal-nucleotide binding sites using a simplified rate equation of the enzyme reaction mechanism. Values of 140 and 2420 microM were obtained for K'm (MgATP) at the first and second sites, respectively, at pH 7.8, with a free Mg2+ of 1 mM and other substrates and activators present at saturating concentrations. Variations of the bicarbonate, N-acetylglutamate, and ammonia concentrations in the absence and presence of different amounts of total calcium, from which free Ca2+, free Mg2+, MgATP2-, and CaATP2- concentrations were calculated, permitted values for K'i (CaATP) to be obtained by graphic procedures. Mean values of 375 and 120 microM were obtained for K'i (CaATP) at the first and second sites, respectively. Using the above kinetic constants, a computer model of the enzyme reaction was constructed and tested using two further sets of kinetic data obtained by varying the concentrations of Mg2+, Ca2+, MgATP2-, and CaATP2-. Poor fits were obtained unless the formation of a mixed complex involving CaATP2- competition with MgATP2- at the second metal-nucleotide-binding site was incorporated into the rate equation. Nonlinear least squares curve fitting of both sets of experimental data gave a well determined value of 124 microM for this final CaATP2- inhibitory constant. Sensitivity tests for variation of the primary kinetic constants with the computer model showed that the inhibitory effect of free Ca2+ was weak and that the observed calcium inhibition of carbamylphosphate synthetase can be accounted for primarily by competitive interaction of CaATP2- at the second MgATP2- binding site. With 1 mM free Mg2+ and 5 mM MgATP2-, half-maximal inhibition of enzyme activity was obtained with 0.2 mM CaATP2-.     

A kinetic study of pig liver pyruvate kinase activated by fructose diphosphate

The paper reports a study of the reaction between phosphoenolpyruvate, ADP and Mg(2+) catalysed by pig liver pyruvate kinase when activated by fructose diphosphate and K(+). The experimental results are consistent with two non-sequential mechanisms in which the substrates and products of the reaction are phosphoenolpyruvate, ADP, Mg(2+), pyruvate and MgATP. Pyruvate release occurs before ADP binding. Two Mg(2+) ions are involved, though the two Mg(2+)-binding sites cannot be occupied simultaneously. An isomerized enzyme complex forms before release of MgATP. Values were determined for the Michaelis constants of the reaction. Apparent MgATP inhibition constants are also given.     

Fructokinase (Fraction IV) of Pea Seeds

A fructokinase (EC 2.7.1.4) was obtained from pea (Pisum sativum L.) seeds. This enzyme, termed fructokinase (fraction IV), was specific for fructose as substrate and had little activity with glucose or mannose. Excess fructose inhibited the enzyme at the optimum pH (8.2) but not at pH 6.6. MgATP was inhibitory at pH 6.6. The apparent Michaelis-Menten constants at pH 8.2 were 0.057 mm for fructose and 0.10 mm for MgATP. Mg(2+) ions were essential for activity; Mn(2+) could partially replace Mg(2+). Fructokinase (fraction IV) had a requirement for K(+) ions which could be substantially replaced by Rb(+) or NH(4) (+) but not by Na(+). The enzyme was inhibited by MgADP. The possible significance of fructokinase (fraction IV) in plant carbohydrate metabolism is discussed.     

Adenine nucleotide binding at a noncatalytic site of mitochondrial F1-ATPase accelerates a Mg(2+)- and ADP-dependent inactivation during ATP hydrolysis.

The evidence is presented that the ADP- and Mg(2+)-dependent inactivation of MF1-ATPase during MgATP hydrolysis requires binding of ATP at two binding sites: one is catalytic and the second is noncatalytic. Binding of the noncatalytic ATP increases the rate of the inactive complex formation in the course of ATP hydrolysis. The rate of the enzyme inactivation during ATP hydrolysis depends on the medium Mg2+ concentration. High Mg2+ inhibits the steady-state activity of MF1-ATPase by increasing the rate of formation of inactive enzyme-ADP-Mg2+ complex, thereby shifting the equilibrium between active and inactive enzyme forms. The Mg2+ needed for MF1-ATPase inactivation binds from the medium independent from the MgATP binding at either catalytic or noncatalytic sites. The inhibitory ADP molecule arises at the MF1-ATPase catalytic site as a result of MgATP hydrolysis. Exposure of the native MF1-ATPase with bound ADP at a catalytic site to 1 mM Mg2+ prior to assay inactivates the enzymes with kinact 24 min-1. The maximal inactivation rate during ATP hydrolysis at saturating MgATP and Mg2+ does not exceed 10 min-1. The results show that the rate-limiting step of the MF1-ATPase inactivation during ATP hydrolysis with excess Mg2+ precedes binding of Mg2+ and likely is the rate of formation of enzyme with ADP bound at the catalytic site without bound P(i). This complex binds Mg2+ resulting in inactive MF1-ATPase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Kinetic studies of fructokinase I of pea seeds

Fructokinase I of pea seeds has been purified to homogeneity and the enzyme shown to be monomeric, with a molecular weight of 72,000 +/- 4000. The reaction mechanism was investigated by means of initial velocity studies. Both substrates inhibited the enzyme; the inhibition caused by MgATP was linear-uncompetitive with respect to fructose whereas that caused by D-fructose was hyperbolic-noncompetitive against MgATP. The product D-fructose 6-phosphate caused hyperbolic-noncompetitive inhibition with respect to both substrates. MgADP caused noncompetitive inhibition, which gave intercept and slope replots that were linear with D-fructose but hyperbolic with MgATP. Free Mg2+ caused linear-uncompetitive inhibition when either substrate was varied. L-Sorbose and beta, gamma-methyleneadenosine 5'-triphosphate were used as analogs of D-fructose and MgATP, respectively. Inhibition experiments using these compounds indicated that substrate addition was steady-state ordered, with MgATP adding first. The product inhibition experiments were found to be consistent with a steady-state random release of products. The substrate inhibition caused by MgATP was most likely due to the formation of an enzyme-MgATP-product dead-end complex, whereas that caused by D-fructose was due to alternative pathways in the reaction mechanism. The inhibition caused by Mg2+ can be explained in terms of a dead-end complex with either a central complex or an enzyme-product complex.     

Factors affecting the inhibition of yeast plasma membrane ATPase by vanadate

Inhibition of yeast plasma membrane ATPase by vanadate occurs only if either Mg2+ or MgATP2- is bound to the enzyme. The dissociation constant of the complex of vanadate and inhibitory sites is 0.14-0.20 microM in the presence of optimal concentrations of Mg2+ and of the order of 1 microM if the enzyme is saturated with MgATP2-. The dissociation constants of Mg2+ and MgATP2- for the sites involved are 0.4 and 0.62-0.73 mM, respectively, at pH 7. KCl does not increase the affinity of vanadate to the inhibitory sites as was found with (Na+ + K+)-ATPase. On the other hand, the effect of Mg2+ upon vanadate binding is similar to that upon (Na+ + K+)-ATPase, and the corresponding affinity constants of Mg2+ and vanadate for the two enzymes are of the same order of magnitude.     

Optimizing thiophosphorylation in the presence of competing phosphorylation with MALDI-TOF-MS detection

Thiophosphorylation provides a metabolically stable, chemically reactive phosphorylation analogue for analyzing the phosphoproteome in vitro and in vivo. We developed a MALDI-TOF-MS based assay for optimizing thiophosphopeptide production by a kinase even in the presence of Mg(2+) and ATP. We found that Abl kinase thiophosphorylation rates can be "rescued" using Mn(2+) in the presence of Mg(2+). Under our ideal conditions, titration of Mn(2+) and ATPgammaS in the presence of Mg(2+) allowed relatively rapid, highly specific thiophosphorylation by Abl tyrosine kinase, both as purified enzyme and in complex cell extracts.     

The purification and properties of pig spleen phosphofructokinase.

Pig spleen phosphofructokinase has been purified 800-fold with a yield of 17%. Two isoenzymes that appear to be kinetically identical can be separated by DEAE-cellulose column chromatography. In common with the enzyme from other mammalian sources, the spleen enzyme has a pH optimum of 8.2. At pH 7.0 it displays sigmoidal kinetics with respect to fructose 6-phosphate concentration but its co-operative behaviour is very dependent on pH, protein concentration and the concentration of MgATP. MgGTP and MgITP can replace MgATP as phosphate donors but, unlike MgATP, these nucleotides do not cause significant inhibition. Mn2+ and Co2+ (as the metal ion-ATP complexes) act as cofactors and in the free form are far more inhibitory than free Mg2+. The spleen enzyme responds to a wide variety of potential effector molecules: ADP, AMP, cyclic AMP, aspartate, NH4+, fructose 6-phosphate, fructose 1,6-diphosphate and Pi all act as either activators or protectors, whereas Mg-ATP, Mg2+, citrate, phosphoenol-pyruvate and the phosphoglucerates are inhibitors.     

Kinetic mechanism of the Mg2+-dependent nucleotidyl transfer catalyzed by T4 DNA and RNA ligases.

The Mg(2+)-dependent adenylylation of the T4 DNA and RNA ligases was studied in the absence of a DNA substrate using transient optical absorbance and fluorescence spectroscopy. The concentrations of Mg(2+), ATP, and pyrophosphate were systematically varied, and the results led to the conclusion that the nucleotidyl transfer proceeds according to a two-metal ion mechanism. According to this mechanism, only the di-magnesium-coordinated form Mg(2)ATP(0) reacts with the enzyme forming the covalent complex E.AMP. The reverse reaction (ATP synthesis) occurs between the mono-magnesium-coordinated pyrophosphate form MgP(2)O(7)(2-) and the enzyme.MgAMP complex. The nucleotide binding rate decreases in the sequence ATP(4-) > MgATP(2-) > Mg(2)ATP(0), indicating that the formation of the non-covalent enzyme.nucleotide complex is driven by electrostatic interactions. T4 DNA ligase shows notably higher rates of ATP binding and of subsequent adenylylation compared with RNA ligase, in part because it decreases the K(d) of Mg(2+) for the enzyme-bound Mg(2)ATP(0) more than 10-fold. To elucidate the role of Mg(2+) in the nucleotidyl transfer catalyzed by T4 DNA and RNA ligases, we propose a transition state configuration, in which the catalytic Mg(2+) ion coordinates to both reacting nucleophiles: the lysyl moiety of the enzyme that forms the phosphoramidate bond and the alpha-beta-bridging oxygen of ATP.     

Functional Approach to the Catalytic Site of the Sarcoplasmic Reticulum Ca2+-ATPase: Binding and Hydrolysis of ATP in the Absence of Ca2+

Isolated sarcoplasmic reticulum vesicles in the presence of Mg(2+) and absence of Ca(2+) retain significant ATP hydrolytic activity that can be attributed to the Ca(2+)-ATPase protein. At neutral pH and the presence of 5 mM Mg(2+), the dependence of the hydrolysis rate on a linear ATP concentration scale can be fitted by a single hyperbolic function. MgATP hydrolysis is inhibited by either free Mg(2+) or free ATP. The rate of ATP hydrolysis is not perturbed by vanadate, whereas the rate of p-nitrophenyl phosphate hydrolysis is not altered by a nonhydrolyzable ATP analog. ATP binding affinity at neutral pH and in a Ca(2+)-free medium is increased by Mg(2+) but decreased by vanadate when Mg(2+) is present. It is suggested that MgATP hydrolysis in the absence of Ca(2+) requires some optimal adjustment of the enzyme cytoplasmic domains. The Ca(2+)-independent activity is operative at basal levels of cytoplasmic Ca(2+) or when the Ca(2+) binding transition is impeded.     

Isotope partitioning in the adenosine 3',5'-monophosphate dependent protein kinase reaction indicates a steady-state random kinetic mechanism

Isotope partitioning beginning with the binary E.MgATP and E.N-acetyl-Leu-Arg-Arg-Ala-Ser-Leu-Gly (Ser-peptide) complexes indicates that the kinetic mechanism for the adenosine 3',5'-monophosphate dependent protein kinase is steady-state random. A total of 100% of the initial radioactive E.MgATP complex is trapped as phospho-Ser-peptide at infinite Ser-peptide concentration at both low and high concentration of uncomplexed Mg2+, suggesting that the off-rate of MgATP from the E.MgATP.Ser-peptide complex is slow relative to the catalytic steps. Km for Ser-peptide in the trapping reaction decreases from 17 microM at low Mg2+ to 2 microM at high Mg2+, indicating that Mg2+ decreases the off-rate for MgATP from the E.MgATP complex. A total of 100% of the radioactive E.Ser-peptide complex is trapped as phospho-Ser-peptide at low Mg2+, but only 40% is trapped at high Mg2+ in the presence of an infinite concentration of MgATP, suggesting that the off-rate for Ser-peptide from the central complex is much less than catalysis at low but not at high Mg2+. In support of this finding, the Ki for Leu-Arg-Arg-Ala-Ala-Leu-Gly (Ala-peptide) increases from 0.27 mM at low Mg2+ to 2.4 mM at high Mg2+. No trapping was observed at either high or low Mg2+ for the E.MgADP complex up to a phospho-Ser-peptide concentration of 5 mM. Thus, it is likely that in the slow-reaction direction the kinetic mechanism is rapid equilibrium.(ABSTRACT TRUNCATED AT 250 WORDS)     

Modulation of cyclin-dependent kinase 4 by binding of magnesium (II) and manganese (II)

All kinases require an essential divalent metal for their activity. In this study, we investigated the metal dependence of cyclin-dependent kinase 4 (CDK4). With Mg(2+) as the essential metal and MgATP being the variable substrate, the maximum velocity, V, was not affected by changes in metal concentration, whereas V/K was perturbed, indicating that the metal effects were mainly derived from a change in the K(m) for MgATP. Analysis of the metal dependence of initial rates according to a simple metal binding model indicated the presence on enzyme of one activating metal-binding site with a dissociation constant, K(d(a)), of 5 +/-1 mM, and three inhibitory metal-binding sites with an averaged dissociation constant, K(d(i)), of 12+/-1 mM and that the binding of metal to the activating and inhibitory sites appeared to be ordered with binding of metal to the activating site first. Substitution of Mn(2+) for Mg(2+) yielded similar metal dependence kinetics with a value of 1.0+/-0.1 and 4.7+/-0.1 for K(d(a)) and K(d(i)), respectively. The inhibition constants for the inhibition of CDK4 by MgADP and a small molecule inhibitor were also perturbed by Mg(2+). K(d(a)) values estimated from the metal variation of the inhibition of CDK4 by MgADP (6+/-3 mM) and a small molecule inhibitor (3+/-1 mM), were in good agreement with the K(d(a)) value (5+/-1 mM) obtained from the metal variation of the initial rate of CDK4. By using the van't Hoff plot, the temperature dependence of K(d(a)) and K(d(i)) yielded an enthalpy of -6.0 +/- 1.1 kcal/mol for binding of Mg(2+) to the activating site and -3.2 +/- 0.6 kcal/mol for Mg(2+) binding to the inhibitory sites. The values of associated entropy were also negative, indicating that these metal binding reactions were entirely enthalpy-driven. These data were consistent with metal binding to multiple sites on CDK4 that perturbs the enzyme structure, modulates the enzyme activity, and alters the affinities of inhibitor for the metal-bound enzyme species. However, the affinities of small molecule inhibitors for CDK4 were not affected by the change of metal from Mg(2+) to Mn(2+), suggesting that the structures of enzyme-Mg(2+) and enzyme-Mn(2+) were similar.     

Differences between manganese and magnesium ions with regard to fatty acid biosynthesis, acetyl-coenzyme A carboxylase activity and malonyl-coenzyme A decarboxylation

Fatty acid-biosynthetic activity in rat liver cytosol fractions is much greater when the bivalent cation in the assay system is Mn(2+) than when it is Mg(2+). This difference between bivalent cations can be abolished if the cytosol fractions are preincubated with isocitrate and the bivalent cation for 30min before assay of fatty acid-biosynthetic activity. In a search for the biochemical basis of this phenomenon, the following differences between Mg(2+) and Mn(2+) were established: (1) Mn(2+) promotes acetyl-CoA carboxylase activity of the protomeric form of the enzyme under conditions in which Mg(2+) does not; (2) Mn(2+)+ATP have little inhibitory effect on the polymerization of acetyl-CoA carboxylase whereas Mg(2+)+ATP are markedly inhibitory; (3) under conditions in which utilization of malonyl-CoA in condensation reactions is prevented, the steady-state concentration of malonyl-CoA formed by a cytosol fraction is much greater with Mn(2+) than with Mg(2+). The role that each of these specific differences between Mn(2+) and Mg(2+) might play in causing liver cytosol preparations to have greater fatty acid-biosynthetic activity in the presence of Mn(2+) is discussed.